Image sensor including plurality of auto focusing pixel groups

ABSTRACT

An image sensor according to an example embodiment include a plurality of image pixel groups, a plurality of auto focusing (AF) pixel groups, a first transmission control signal line connected to a first pixel of each of the plurality of image pixel groups, a second transmission control signal line connected to a second pixel of each of the plurality of image pixel groups, a third transmission control signal line connected to a first pixel of each of the plurality of AF pixel groups, and a fourth transmission control signal line connected to a second pixel of each of the plurality of AF pixel groups, wherein the fourth transmission control signal line is electrically separated from the first to the third transmission control signal line, and the each of the plurality of image pixel group and the plurality of AF pixel groups are disposed below a single microlens.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority from Korean Patent Application No.10-2019-0131686, filed on Oct. 22, 2019 in the Korean IntellectualProperty Office, the disclosure of which is incorporated herein in itsentirety by reference.

BACKGROUND

Apparatuses and methods consistent with one or more exemplaryembodiments relate to an image sensor, and more particularly, to animage sensor including a plurality of auto focusing (AF) pixel groups.

An image sensor that captures an image and converts the image into anelectrical signal is used in a consumer electronic device, such as adigital camera, a mobile phone camera, or a portable camcorder, as wellas a camera mounted in an automobile, a security device, or a robot. Theimage sensor includes a pixel array, and each pixel included in thepixel array may include a photodiode. The image sensor needs to performan AF function such that an image may be accurately captured in a shorttime.

SUMMARY

Aspects of one or more exemplary embodiments provide an image sensorcapable of quickly performing an AF function.

According to an aspect of an exemplary embodiment, there is provided animage sensor including: a pixel array including a plurality of imagepixel groups and a plurality of auto focusing (AF) pixel groups, each ofthe plurality of image pixel groups and the plurality of AF pixel groupsincluding a plurality of pixels; a first transmission control signalline connected to a first pixel of each of the plurality of image pixelgroups; a second transmission control signal line connected to a secondpixel of each of the plurality of image pixel groups; a thirdtransmission control signal line connected to a first pixel of each ofthe plurality of AF pixel groups; and a fourth transmission controlsignal line connected to a second pixel of each of the plurality of AFpixel groups, wherein the fourth transmission control signal line iselectrically separated from the first to the third transmission controlsignal line, and wherein the each of the plurality of image pixel groupand the plurality of AF pixel groups are disposed below a singlemicrolens.

According to an aspect of another exemplary embodiment, there isprovided an image sensor including: a pixel array including a pluralityof pixels on a first row in a first direction and a plurality pixelsarranged on a second row in the first direction, the second row beingarranged next to the first row in a second direction perpendicular tothe first direction, the plurality of pixels on the first row includinga first to an eighth pixels, the plurality of pixels on the second rowincluding a first to an eighth pixels; and a first transmission controlsignal line connected to the first pixel, the fifth pixel, and theseventh pixel among the plurality of pixels on the first row, whereinthe first pixel, the fifth pixel, and the seventh pixel among theplurality of pixels on the first row are sequentially arranged in thefirst direction, wherein each of the plurality of pixels on the firstrow is included in a corresponding pixel group among a plurality pixelgroup, and each of the plurality of pixel group is disposed below asingle microlens.

According to an aspect of another exemplary embodiment, there isprovided an image sensor including: a pixel array including a pluralityof first pixels on a first row in a first direction and a plurality ofsecond pixels arranged on a second row in the first direction, thesecond row being arranged next to the first row in a second directionperpendicular to the first direction; a first transmission control lineconnected to N numbers of pixels of the plurality of first pixels; asecond transmission control line connected to M numbers of pixels of theplurality of first pixels; a third transmission control line connectedto K numbers of pixels of the plurality first pixels, wherein each ofthe plurality of pixels on the first row is included in a correspondingpixel group among a plurality pixel group, and each of the plurality ofpixel group is disposed below a single microlens, wherein the N, the Mand the K are integer, and the K is less than or equal to ⅓ of each ofthe N and the M.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments will be more clearly understood from the following detaileddescription taken in conjunction with the accompanying drawings inwhich:

FIG. 1 is a diagram illustrating a structure of a digital imaging deviceaccording to an exemplary embodiment;

FIG. 2 is a block diagram illustrating a configuration of an imagesensor according to another exemplary embodiment;

FIG. 3 is a diagram illustrating an exemplary connection between a rowdriver and a pixel array of FIG. 2;

FIG. 4 is an example circuit diagram of a first pixel group of FIG. 3;

FIG. 5 is an exemplary timing diagram illustrating transmission controlsignals and mode control signals provided to each of a plurality ofpixel groups and a plurality of AF pixel groups of FIG. 3;

FIGS. 6A, 6B, and 7 are diagrams illustrating another exemplaryconnection between the row driver and the pixel array of FIG. 2;

FIG. 8 is an exemplary timing diagram illustrating the transmissioncontrol signals provided to each of the plurality of pixel groups andthe plurality of AF pixel groups of FIG. 7;

FIGS. 9A and 9B are diagrams illustrating another exemplary connectionbetween the row driver and the pixel array of FIG. 2;

FIG. 10A is an exemplary layout of a first pixel group and a first AFpixel group included in a sixth pixel array of FIG. 9B;

FIG. 10B is a cross-sectional view taken along line X1-X2 of FIG. 10A;

FIG. 10C is an exemplary circuit diagram of the first AF pixel group ofFIG. 10A;

FIG. 11A is an exemplary layout of the first pixel group and the firstAF pixel group included in the sixth pixel array of FIG. 9B;

FIG. 11B is another exemplary circuit diagram of the first AF pixelgroup of FIG. 11A;

FIGS. 12A through 12C are diagrams illustrating another exemplaryconnection between the row driver and the pixel array of FIG. 2; and

FIGS. 13A to 13C are diagrams illustrating another exemplary connectionbetween the row driver and the pixel array of FIG. 2.

DETAILED DESCRIPTION

FIG. 1 is a diagram illustrating a structure of a digital imaging device1000 according to an exemplary embodiment.

Referring to FIG. 1, the digital imaging device 1000 according to theexemplary embodiment may include an imaging unit 1100, an image sensor100, and a processor 1200. The digital imaging device 1000 may have afocus detection function.

Operations of the digital imaging device 1000 may be controlled by theprocessor 1200. The processor 1200 may provide a control signal for anoperation of each component to a lens driver 1120, an aperture driver1140, a controller 120, and so on.

The imaging unit 1100 may be a configuration element for receiving lightand may include a lens 1110, the lens driver 1120, an aperture 1130, andthe aperture driver 1140. The lens 1110 may include a plurality oflenses.

The lens driver 1120 may transmit and receive information on focusdetection to and from the processor 1200 and adjust a position of thelens 1110 according to a control signal provided from the processor1200. The lens driver 1120 may move the lens 1110 in a direction inwhich a distance to an object 2000 increases or decreases, and adistance between the lens 1110 and the object 2000 may be adjusted. Theobject 2000 may be focused or blurred depending on the position of thelens 1110.

The image sensor 100 may convert incident light into an image signal.The image sensor 100 may include a pixel array 110, the controller 120,and a signal processor 130. An optical signal transmitted through thelens 1110 and the aperture 1130 may reach a light receiving surface ofthe pixel array 110 to form an image of a subject (i.e., the object2000).

The pixel array 110 may be a complementary metal oxide semiconductorimage sensor (CIS) that converts an optical signal into an electricalsignal. Sensitivity and the like of the pixel array 110 described abovemay be adjusted by the controller 120. The pixel array 110 may includepixels for performing at least one of an auto focusing (AF) function ora distance measurement function.

The image sensor 100 may provide an image signal to the processor 1200,and the processor 1200 may perform a phase difference calculation byusing the image signal. The processor 1200 may obtain at least one of aposition of focus, a direction of the focus, a distance between theobject 2000 and the image sensor 100, etc., from a result of the phasedifference calculation. The processor 1200 may output a control signalto the lens driver 1120 to move the position of the lens 1110 based onthe result(s) of the phase difference calculation.

In the present exemplary embodiment, the image sensor 100 may perform AFoperations of a first mode and a second mode. For example, in the firstmode, the image sensor 100 may provide an image signal including AFinformation to the processor 1200 based on a pixel signal output fromeach of pixels included in the pixel array 110. In the second mode, theimage sensor 100 may provide an image signal including the AFinformation to the processor 1200 based on pixel signals output from thepixels included in a plurality of AF pixel groups among a plurality ofpixel groups and the plurality of AF pixel groups included in the pixelarray 110. The image sensor may be configured to provide a highresolution AF function in the first mode or provide a high speed AFfunction in the second mode, thereby efficiently providing the AFfunction in various situations. It is understood that one or more otherexemplary embodiments are not limited thereto, and in another exemplaryembodiment, the image sensor 100 may not operate in the first mode butmay perform only the AF operation of the second mode.

FIG. 2 is a block diagram illustrating a configuration of an imagesensor 100 according to an exemplary embodiment.

Referring to FIG. 2, the image sensor 100 may include the pixel array110, the controller 120, the signal processor 130, a row driver 140, anda signal reader 150. The signal reader 150 may include acorrelated-double sampling circuit (CDS) 151, an analog-to-digitalconverter (ADC) 153, and a buffer 155.

The pixel array 110 may include a plurality of pixel groups PG (forexample, PX of FIG. 3), each including a plurality of pixels, and aplurality of AF pixel groups PG_AF. A ratio of the plurality of AF pixelgroups PG_AF to the plurality of pixel groups PG in the pixel array 110may be adjusted in various ways. A structure of the plurality of pixelsPX included in the pixel array 110 is described below with reference toFIGS. 3 to 5, 6A to 6B, 7 to 8, 9A to 9B, 10A to 10C, 11A to 11B, 12A to12C, and 13A to 13C. In this case, each of the plurality of pixel groupsPG which are different from the plurality of AF pixel groups PG_AF maybe referred to as an image pixel group.

The pixel array 110 may output the pixel signals to a CDS 151 throughfirst through n-th column output lines CLO_0 to CLO_n-1. In the presentexemplary embodiment, the pixel signals output from a plurality ofpixels PX included in each of the plurality of pixel groups PG and theplurality of AF pixel groups PG_AF may be phase signals used tocalculate a phase difference in the first mode. In addition, in thesecond mode, the pixel signals output from some selected pixels amongthe plurality of pixels PX included in each of the plurality of AF pixelgroups PG_AF may be the phase signals used to calculate the phasedifference. The phase signals may include information on positions ofimages formed in the image sensor 100, and a focal position of the lens1110 of FIG. 1 may be calculated based on the calculated phasedifference. For example, the position of the lens 1110 of FIG. 1 thatmakes the phase difference zero may be the focal position.

That is, in the first mode, the pixel signals output from each of theplurality of pixel groups PG and the plurality of AF pixel groups PG_AFmay include AF information. In contrast to this, in the second mode, thepixel signals output from each of the plurality of AF pixel groups PG_AFmay include the AF information, and the pixel signals output from theplurality of pixel groups PG may not include the AF information.

The phase signals may be used not only to focus on the object 2000, butalso to measure a distance between the object 2000 and the image sensor100. In order to measure the distance between the object 2000 and theimage sensor 100, additional information may be referred to, such as atleast one of the phase difference between the images formed in the imagesensor 100, a distance between the lens 1110 and the image sensor 100, asize of the lens 1110, a focal position of the lens 1110, and so on.

The controller 120 may control the row driver 140 to make the pixelarray 110 absorb light to accumulate charges or temporarily store theaccumulated charges and to make the pixel array 110 output an electricalsignal according to the stored charges to the outside. In addition, thecontroller 120 may control the signal reader 150 to measure a level ofthe pixel signal provided by the pixel array 110.

The row driver 140 may generate control signals RSs, TSs, and SELSs forcontrolling the pixel array 110 and provide the generated controlsignals to the pixel array 110. In the present exemplary embodiment, therow driver 140 may determine activation timing and deactivation timingof the reset control signals RSs, the transmission control signals TSs,and the selection signals SELSs provided to the respective pixels PXincluded in each of the plurality of pixel groups PG and the pluralityof AF pixel groups PG_AF to perform the first mode or the second mode.

In the present exemplary embodiment, the row driver 140 may provide thetransmission control signals TSs such that each of the plurality ofpixels PX included in the plurality of pixel groups PG and the pluralityof AF pixel groups PG_AF may generate the pixel signal as a phase signalin the first mode. In addition, in the second mode, the row driver 140may provide the transmission control signals TSs to block generation of(or control not to generate) the pixel signal according to photo-chargesconverted by some pixels (e.g., some selected or predetermined pixels)among the plurality of pixels PX included in the plurality of AF pixelgroups PG_AF. That is, in the second mode, as only other pixels (e.g.,other selected or predetermined pixels) from among the plurality ofpixels PX included in the plurality of AF pixel groups PG_AF arecontrolled to output the pixel signal as a phase signal, the imagesensor 100 may have or obtain pixel signals including the AF informationoutput from the plurality of AF pixel groups PG_AF, even when the pixelsignals output from the plurality of pixel groups PG do not include theAF information. Accordingly, the image sensor 100 may perform the firstmode to provide a high resolution AF function and may perform the secondmode to provide a high speed AF function.

The CDS 151 may sample and hold the pixel signals provided by the pixelarray 110. The CDS 151 may double-sample a level of a predeterminednoise and a level according to a pixel signal and output a levelcorresponding to a difference therebetween. In addition, the CDS 151 mayreceive ramp signals generated by the ramp signal generator 157, comparethe ramp signals with each other, and output comparison results. Theanalog-to-digital converter 153 may convert an analog signalcorresponding to a level received from the CDS 151 into a digitalsignal. The buffer 155 may latch the digital signal, and the latchedsignal may be sequentially output to the outside of the signal processor130 or the image sensor 100.

The signal processor 130 may perform signal processing based on thedigital signal received from the buffer 155. For example, the signalprocessor 130 may perform at least one of noise reduction processing,gain adjustment, waveform shaping processing, interpolation processing,white balance processing, gamma processing, edge emphasis processing,and so on. In addition, the signal processor 130 may output thesignal-processed image signal to the processor 1200 during the AFoperation to perform a phase difference calculation for the AFoperation. In the present exemplary embodiment, the signal processor 130may be included in the processor 1200 of FIG. 1 outside the image sensor100.

FIG. 3 is a diagram illustrating an exemplary connection between the rowdriver 140 and the pixel array 110 of FIG. 2, and illustrates a part ofthe pixel array 110 and transmission control signal lines. The pixelarray 110 of FIG. 2 may include a first pixel array 110_1.

In FIG. 3 and the following drawings, a connection relationship betweenthe pixels PX and each of transmission control signal lines TGL1, TGR1,TGL2, and TGR2 and mode control signal lines TGEL and TGER isillustrated through a connection CNT. Signals provided through thetransmission control signal lines TGL1, TGR1, TGL2, and TGR2 and themode control signal lines TGEL and TGER may be the transmission controlsignals TSs of FIG. 1. That is, the mode control signal lines TGEL andTGER may also be lines for transmitting signals provided to a gate of atransmission included in the pixel.

Although FIG. 3 and the following drawings illustrate that a firstdirection X is a row direction and a second direction Y is a columndirection, it is understood that this is just one example. The seconddirection Y may be the row direction and the first direction X may bethe column direction in another exemplary embodiment.

Referring to FIG. 3, the first pixel array 110_1 may include theplurality of pixel groups PG and the plurality of AF pixel groups PG_AF.Each of the plurality of pixel groups PG may include the plurality ofpixels PX arranged in one row and two columns and one microlens MLdisposed over the plurality of pixels PX. That is, each of the pluralityof pixel groups PG may include a first pixel and a second pixel arrangedside by side in the first direction X. The microlenses ML included inthe first pixel array 110_1 may have the same shape and a constant size.

In the present exemplary embodiment, each of the plurality of pixelgroups PG may include at least one of a green color filter G, a redcolor filter R, and a blue color filter B. For example, the first pixelgroup PG1 and the second pixel group PG2 may include the red colorfilters R, the third pixel group PG3 and the fourth pixel group PG4 mayinclude the green color filters R, and the fifth pixel group PG5 and thesixth pixel group PG6 may include the blue color filters B. It isunderstood, however, that one or more exemplary embodiments are notlimited thereto. For example, according to another exemplary embodiment,each of the plurality of pixel groups PG may include a white colorfilter or a yellow color filter.

Each of the plurality of AF pixel groups PG_AF may include the pluralityof pixels PX arranged in one row and two columns and one microlens MLdisposed over the plurality of pixels PX. In the present exemplaryembodiment, each of the plurality of AF pixel groups PG_AF may include agreen color filter GAF.

Further, in the present exemplary embodiment, the plurality of pixelgroups PG and the plurality of AF pixel groups PG_AF of the first pixelarray 110_1 may include color filters to correspond to a Bayer pattern.The inventive concept(s) is not limited thereto, and according toanother exemplary embodiment, each of the plurality of AF pixel groupsPG_AF may include at least one of the red color filter, the blue colorfilter, the white color filter, and the yellow color filter.

The pixels PX included in the plurality of pixel groups PG may beconnected to corresponding transmission control signal lines of thetransmission control signal lines TGL1, TGR1, TGL2, and TGR2. Forexample, first pixels included in the first pixel group PG1 to the thirdpixel group PG3 may be connected to the first transmission controlsignal line TGL1, and second pixels included in the first pixel groupPG1 to the third pixel group PG3 may be connected to the secondtransmission control signal line TGR1. In addition, for example, thefirst pixels included in the fourth pixel group PG4 to the sixth pixelgroup PG6 may be connected to the third transmission control signal lineTGL2, and the second pixels included in the fourth pixel group PG4 tothe sixth pixel group PG6 may be connected to the fourth transmissioncontrol signal line TGR2.

Some of the pixels PX included in the plurality of AF pixel groups PG_AFmay be connected to a corresponding transmission control signal lineamong the transmission control signal lines TGL1, TGR1, TGL2, and TGR2,and the other of the pixels PX included in the plurality of AF pixelgroups PG_AF may be connected to a corresponding mode control signalline of the mode control signal lines TGEL and TGER. For example, thefirst pixel disposed in a first column of the pixels PX included in thefirst AF pixel group PG_AF1 may be connected to the first mode controlsignal line TGEL and the second pixel disposed in a second column of thepixels PX included in the first AF pixel group PG_AF1 may be connectedto the second transmission control signal line TGR1. Alternatively, forexample, the first pixel disposed in the first column of the pixels PXincluded in the second AF pixel group PG_AF2 may be connected to thethird transmission control signal line TGL2 and the second pixeldisposed in the second column of the pixels PX included in the second AFpixel group PG_AF2 may be connected to the fourth mode control signalline TGER. Accordingly, the image sensor according to an exemplaryembodiment may provide the AF function in the first direction X by usingthe pixel signal output from the first AF pixel group PG_AF1 and thepixel signal output from the second AF pixel group PG_AF2.

Although FIG. 3 illustrates that the first AF pixel group PG_AF1 and thesecond AF pixel group PG_AF2 are arranged in different rows and columns,it is understood that one or more other exemplary embodiments are notlimited thereto. For example, according to another exemplary embodiment,the first AF pixel group PG_AF1 and the second AF pixel group PG_AF2 maybe arranged in the same row or the same column.

In an exemplary embodiment, when the first transmission control lineTGL1 connected to N numbers of pixels PX on a first row in the firstdirection X, the second transmission control line TGR1 connected to Mnumbers of pixels PX in the first row in the first direction X, and thefirst mode control signal line TGEL connected to K numbers of pixels PXin the first row in the first direction X, the K may be less than orequal to ⅓ of each of the N and the M. It is understood, however, thatone or more other exemplary embodiments are not limited thereto, and theK may be less than or equal to ⅕, ⅛, or 1/15 of each of the N and the M,according to an arrangement structure of the pixels included in thepixel groups PG1, PG2, PG3, PG4, PG5, and PG6, and the AF pixel groupsPG_AF1, and PG_AF2.

FIG. 4 is an exemplary circuit diagram of the first pixel group PG1 ofFIG. 3. FIG. 4 illustrates an exemplary embodiment in which the pixelsincluded in the first pixel group share a floating diffusion region,and, for the convenience of description, the same may be applied to theplurality of pixel groups PG and the plurality of AF pixel groups PG_AF.In the present exemplary embodiment, the plurality of pixels PX includedin the same pixel group among the plurality of pixel groups PG may sharethe floating diffusion region, and the plurality of pixels PX includedin the same AF pixel group among the plurality of AF pixel groups PG_AFmay share the floating diffusion region. It is understood, however, thatone or more other exemplary embodiments are not limited thereto, andthree or more pixels may share the floating diffusion region.

Referring to FIG. 4, the first pixel disposed in the first column of thefirst pixel group PG1 may include a first photodiode PD11, a firsttransmission transistor TX11, a selection transistor SX1, a drivetransistor SF1, and a reset transistor RX1. The second pixel disposed inthe second column of the first pixel group PG1 may include a secondphotodiode PD12, a second transmission transistor TX12, the selectiontransistor SX1, the drive transistor SF1, and the reset transistor RX1.The first pixel and the second pixel may form a shared pixel structurein which a floating diffusion region FD1 is shared and the selectiontransistor SX1, the drive transistor SF1, and the reset transistor RX1are shared with each other. In the present exemplary embodiment, atleast one of the selection transistor SX1, the drive transistor SF1, andthe reset transistor RX1 may be omitted.

Each of the first photodiode PD11 and the second photodiode PD12 maygenerate photo-charges that vary according to light intensity. Forexample, each of the first photodiode PD11 and the second photodiodePD12 is a PN junction diode, which generates charges, that is, electronsthat are negative charges and holes that are positive charges, inproportion to the amount of incident light. Each of the first photodiodePD11 and the second photodiode PD12 is an example of a photoelectricconversion element, and may be at least one of a photo transistor, aphoto gate, a pinned photo diode (PPD), and a combination thereof.

The floating diffusion region FD1 may operate as a capacitor. The firsttransmission transistor TX11 may transmit the photo-charges generated bythe first photodiode PD11 to the floating diffusion region FD1 accordingto the first transmission control signal TS11. If (or based on) thefirst transmission transistor TX11 is turned on, the photo-chargesgenerated by the first photodiode PD11 may be transmitted to thefloating diffusion region FD1 to be accumulated and stored therein. Thesecond transmission transistor TX12 may transmit the photo-chargesgenerated by the first photodiode PD12 to the floating diffusion regionFD1 according to the second transmission control signal TS12.

The reset transistor RX1 may periodically reset the charges accumulatedin the floating diffusion region FD1. A source electrode of the resettransistor RX1 may be connected to the floating diffusion region FD1 anda drain electrode of the reset transistor RX1 may be connected to apower supply voltage VPIX. If (or based on) the reset transistor RX1 isturned on according to the reset control signal RS1, the power supplyvoltage VPIX connected to the drain electrode of the reset transistorRX1 is transmitted to the floating diffusion region FD1. When (or basedon) the reset transistor RX1 is turned on, the charges accumulated inthe floating diffusion region FD1 may be discharged to reset thefloating diffusion region FD1.

The drive transistor SF may be controlled according to the amount ofphoto-charges accumulated in the floating diffusion region FD1. Thedrive transistor SF may buffer a signal according to the charges chargedin the floating diffusion region FD1 as a buffer amplifier. The drivetransistor SF may amplify a potential change in the floating diffusionregion FD1 and output the amplified potential change to a column outputline (for example, one column output line of a first column output lineCLO_0 to an n-th column output line CLO_n-1 of FIG. 2) as a pixel signalVOUT.

The selection transistor SX1 having a drain terminal connected to asource terminal of the drive transistor SF may output the pixel signalVOUT to the CDS (for example, 151 of FIG. 2) through a column outputline in response to a selection signal SELS1.

FIG. 5 is an exemplary timing diagram illustrating the transmissioncontrol signal and the mode control signal provided to each of theplurality of pixel groups PX and the plurality of AF pixel groups PX_AFof FIG. 3.

Referring to FIGS. 3 and 5, the first to fourth transmission controlsignals TS1, TS2, TS3, and TS4 provided through the first to fourthtransmission control signal lines TGL1, TGR1, TGL2, and TGR2 may besequentially changed from a logic low to a logic high in the first mode.For example, the first transmission control signal TS1 may change from alogic low to a logic high at a first time T1 and may change from thelogic high to the logic low at a second time T2. The second transmissioncontrol signal TS2 may change from the logic low to the logic high at athird time T3 and may change from the logic high to the logic low at afourth time T4. The third transmission control signal TS3 may changefrom the logic low to the logic high at a fifth time T5 and may changefrom the logic high to the logic low at a sixth time T6. The fourthtransmission control signal TS4 may change from the logic low to thelogic high at a seventh time T7 and may change from the logic high tothe logic low at an eighth time T8.

Further, a first mode control signal TSAF1 provided to the first modecontrol signal line TGEL may change from the logic low to the logic highat the first time T1 and may change from the logic high to the logic tolow at the second time T2. That is, the first mode control signal TSAF1may be activated at the same timing as the timing of the firsttransmission control signal TS1. A second mode control signal TSAF2provided to the second mode control signal line TGER may change from thelogic low to the logic high at the seventh time T7 and may change fromthe logic low to the logic low at the eighth time T8. That is, thefourth transmission control signal TS4 and the second mode controlsignal TSAF2 may be activated at the same timing.

In the first mode, the image sensor according to an exemplary embodimentmay perform the AF function in the first direction X that is a rowdirection by using the first pixel signals corresponding to thephoto-charges generated by the first pixels arranged in the first columnof the plurality of pixel groups PG and the plurality of AF pixel groupsPG_AF and the second pixel signals corresponding to the photo-chargesgenerated by the second pixels arranged in the second column thereof.Accordingly, in the first mode, the image sensor generates AFinformation from the plurality of pixel groups PG and the plurality ofAF pixel groups PG_AF, thereby providing a high resolution AF function.

In the second mode, the first transmission control signal TS1 and thesecond transmission control signal TS2, which are provided through thefirst transmission control signal line TGL1 and the second transmissioncontrol signal line TGR1, respectively, may change from the logic low tothe logic high at a first time T1′ and may change from the logic high tothe logic low at a second time T2′. At this time, the first mode controlsignal TSAF1 provided to the first mode control signal line TGEL maymaintain the logic low. That is, the first mode control signal TSAF1 maybe deactivated. Accordingly, the first pixels and the second pixelsincluded in each of the first pixel group PG1 to the third pixel groupPG3 may simultaneously accumulate photo-charges in the shared floatingdiffusion region, and the pixel signals (for example, VOUT of FIG. 4)output from each of the first pixel group PG1 to the third pixel groupPG3 may not include the AF information. In contrast to this, the firstmode control signal TSAF1 provided to the first pixel of the first AFpixel group PG_AF1 maintains the logic low, and thus, the pixel signaloutput from the first AF pixel group PG_AF1 may be the second pixelsignal corresponding to the photo-charges generated by the second pixelof the first AF pixel group PG_AF1.

In the second mode, the third transmission control signal TS3 and thefourth transmission control signal TS4, which are provided through thethird transmission control signal line TGL2 and the fourth transmissioncontrol signal line TGR2, respectively, may change from the logic low tothe logic high at a third time T3′ and may change from the logic high tothe logic low at a fourth time T4′. At this time, the second modecontrol signal TSAF2 provided to the second mode control signal lineTGER may maintain the logic low. That is, the second mode control signalTSAF2 may be deactivated. Accordingly, the first pixels and the secondpixels included in each of the fourth pixel group PG4 to the sixth pixelgroup PG6 may simultaneously accumulate photo-charges in the sharedfloating diffusion region, and the pixel signals output from each of thefourth pixel group PG4 to the sixth pixel group PG6 may not include theAF information. In contrast to this, the second mode control signalTSAF2 provided to the second pixel of the second AF pixel group PG_AF2maintains the logic low, and thus, the pixel signals output from thesecond AF pixel group PG_AF2 may be the first pixel signal correspondingto the photo-charges generated by the first pixel of the second AF pixelgroup PG_AF2.

In the second mode, the image sensor according to an exemplaryembodiment may perform the AF function in the direction X by using thesecond pixel signal output from the first AF pixel group PG_AF1 and thefirst pixel signal output from the second AF pixel group PG_AF2.Accordingly, in the second mode, the image sensor may provide arelatively high speed AF function.

FIGS. 6A and 6B are diagrams illustrating an exemplary connectionbetween the row driver 140 and the pixel array 110 of FIG. 2 andillustrate a part of the pixel array 110 and transmission control signallines connected to a part of the pixel array 110. In describing FIGS. 6Aand 6B, redundant descriptions of the same symbols or components as inFIG. 3 may be omitted. The pixel array 110 of FIG. 2 may include atleast one of a second pixel array 110_1 a and a third pixel array 110_1b.

Referring to FIG. 6A, the second pixel array 110_1 a may include aplurality of pixel groups PGa and a plurality of AF pixel groups PG_AFa.The plurality of pixels PX included in first pixel group PG1 a to thirdpixel group PG3 a may be connected to the transmission control signalline TG1 and the plurality of pixels PX included in fourth pixel groupPG4 a to sixth pixel group PG6 a may be connected to the transmissioncontrol signal line TG2.

Among the pixels PX included in first AF pixel group PG_AF1 a, the firstpixel disposed in the first column may be connected to the first modecontrol signal line TGEL, and the second pixel disposed in the secondcolumn may be connected to the transmission control signal line TG1.Among the pixels PX included in the second AF pixel group PG_AF2 a, thefirst pixel disposed in the first column may be connected to thetransmission control signal line TG2, and the second pixel disposed inthe second column may be connected to the second mode control signalline TGER. When (or based on) the AF operation is performed, the firstmode control signal provided to the first mode control signal line TGELmay maintain a logic low and the second mode control signal provided tothe second mode control signal line TGER may maintain a logic low.

In an exemplary embodiment, when the transmission control line TG1connected to N numbers of pixels PX on a first row in the firstdirection X, and the first mode control signal line TGEL connected to Knumbers of pixels PX in the first row in the first direction X, the Kmay be less than or equal to 1/7 of the N. It is understood, however,that one or more other exemplary embodiments are not limited thereto.

Referring to FIG. 6B, the third pixel array 110_1 b may include aplurality of pixel groups PGb and a plurality of AF pixel groups PG_AFb.The plurality of pixels PX included in first pixel group PG1 b to thirdpixel group PG3 b may be connected to the transmission control signalline TG1 and the plurality of pixels PX included in fourth pixel groupPG4 b to sixth pixel group PG6 b may be connected to the transmissioncontrol signal line TG2.

Some of the pixels PX included in the plurality of AF pixel groupsPG_AFb may be connected to one corresponding line among the transmissioncontrol signal lines TG1 and TG2, and other of the pixels PX included inthe plurality of AF pixel groups PG_AFb may not be connected to thetransmission control signal lines TG1 and TG2.

Referring to FIGS. 6A and 6B, the image sensor according to an exemplaryembodiment may perform the AF operation of the second mode. The imagesensor may perform the AF function in the first direction X by using thesecond pixel signal output from the first AF pixel group PG_AF1 a orPG_AF1 b and the first pixel signal output from the second AF pixelgroup PG_AF2 a or PG_AF2 b, thereby providing a relatively high speed AFfunction.

FIG. 7 is a diagram illustrating another exemplary connection betweenthe row driver 140 and the pixel array 110 of FIG. 2 and illustrates apart of the pixel array 110 and the transmission control signal linesconnected to a part of the pixel array 110. FIG. 8 is an exemplarytiming diagram illustrating the transmission control signals provided toeach of the plurality of pixel groups PX and the plurality of AF pixelgroups PX_AF of FIG. 7. In FIG. 7, redundant descriptions of the samesymbols or components as in FIG. 3 may be omitted. The pixel array 110of FIG. 2 may include a fourth pixel array 110_2.

Referring to FIG. 7, the fourth pixel array 110_2 may include aplurality of pixel groups PGc and a plurality of AF pixel groups PG_AFc.Each of the plurality of pixel groups PGc may include the plurality ofpixels PX arranged in two rows and two columns and one microlens MLdisposed over the plurality of pixels PX. That is, each of the pluralityof pixel groups PG may include the first pixel disposed in the first rowand the first column, the second pixel disposed in the first row and thesecond column, a third pixel disposed in the second row and the firstcolumn, and a fourth pixel disposed in the second row and the secondcolumn. In the present exemplary embodiment, the first pixel to thefourth pixel included in the same pixel group among the plurality ofpixel groups PG may share the floating diffusion region.

The first pixels included in first pixel group PG1 c to third pixelgroup PG3 c may be connected to a first transmission control signal lineTGL11A, the second pixels may be connected to a second transmissioncontrol signal line TGR11A, the third pixels may be connected to a thirdtransmission control signal line TGL12A, and the fourth pixels may beconnected to a fourth transmission control signal line TGR12A. The firstpixels included in the fourth pixel group PG4 c to the sixth pixel groupPG6 c may be connected to a fifth transmission control signal lineTGL21A, the second pixels may be connected to a sixth transmissioncontrol signal line TGR21A, the third pixels may be connected to aseventh transmission control signal line TGL22A, and the fourth pixelsmay be connected to an eighth transmission control signal line TGR22A.

Some of the pixels PX included in the plurality of AF pixel groupsPG_AFc may be connected to a corresponding line among the transmissioncontrol signal lines TGL11A to TGR22A, and other of the pixels PXincluded in the plurality of AF pixel groups PG_AFc may be connected toa corresponding line of the mode control signal lines TGEL1A, TGEL2A,TGER1A, and TGER2A. For example, among the pixels PX included in thefirst AF pixel group PG_AF1 c, the first pixel and the third pixeldisposed in the first column may be respectively connected to the firstmode control signal line TGEL1A and the third mode control signal lineTGEL2A, and the second pixel and the fourth pixel disposed in the secondcolumn may be respectively connected to the second transmission controlsignal line TGR11A and the fourth transmission control signal lineTGR12A. In addition, for example, among the pixels PX included in thesecond AF pixel group PG_AF2 c, the second pixel and the fourth pixeldisposed in the second column may be respectively connected to thesecond mode control signal line TGER1A and the fourth mode controlsignal line TGER2A, and the first pixel and the third pixel disposed inthe first column may be respectively connected to the fifth transmissioncontrol signal line TGL21A and the seventh transmission control signalTGL22A.

In an exemplary embodiment, when the first transmission control lineTGL11A connected to N numbers of pixels PX on a first row in the firstdirection X, the second transmission control line TGR11A connected to Mnumbers of pixels PX in the first row in the first direction X, and thefirst mode control signal line TGEL1A connected to K numbers of pixelsPX in the first row in the first direction X, the K may be less than orequal to ⅓ of each of the N and the M. It is understood, however, thatone or more other exemplary embodiments are not limited thereto.Referring to FIGS. 7 and 8, in the first mode, the first and thirdtransmission control signals TS1A and TS3A provided through the firstand third transmission control signal lines TGL11A and TGL12A,respectively, may change from a logic low to a logic high at a firsttime T1A and may change from the logic high to the logic low at a secondtime T2A. In addition, the first and third mode control signals TSAF11and TSAF12 provided through the first and third mode control signallines TGEL1A and TGEL2A, respectively, may change from the logic low tothe logic high at the first time T1A and may change from the logic highto the logic low at the second time T2A.

The second and fourth transmission control signals TS2A and TS4Aprovided through the second and fourth transmission control signal linesTGR11A and TGR12A, respectively, may change from the logic low to thelogic high at a third time T3A and may change from the logic high to thelogic low at a fourth time T4A. The fifth and seventh transmissioncontrol signals TS5A and TS7A provided through the fifth and seventhtransmission control signal lines TGL21A and TGL22A, respectively, maychange from the logic low to the logic high at a fifth time T5A and maychange from the logic high to the logic low at a sixth time T6A.

The sixth and eighth transmission control signals TS6A and TS8A providedthrough the sixth and eighth transmission control signal lines TGR21Aand TGR22A, respectively, may change from the logic low to the logichigh at a seventh time T7A and may change from the logic high to thelogic low at an eighth time T8A. In addition, the second and fourth modecontrol signals TSAF21 and TSAF22 provided through the second and fourthmode control signal lines TGER1A and TGER2A, respectively, may changefrom the logic low to the logic high at the seventh time T7A and maychange from the logic high to the logic low at the eighth time T8A.

In the first mode, the image sensor according to an exemplary embodimentmay perform the AF function in the first direction X, which is a rowdirection, by using the first pixel signals corresponding to thephoto-charges generated by the first pixels and the third pixelsdisposed in the first column of the plurality of pixel groups PGc andthe plurality of AF pixel groups PG_AFc and the second pixel signalscorresponding to the photo-charges generated by the second pixels andthe fourth pixels disposed in the second column thereof. Accordingly, inthe first mode, the image sensor may generate AF information from theplurality of pixel groups PGc and the plurality of AF pixel groupsPG_AFc and may provide a high resolution AF function.

Conversely, in the second mode, the first to fourth transmission controlsignals TS1A to TS4A provided through the first to fourth transmissioncontrol signal lines TGL11A, TGR11A, TGL12A, and TGR12A, respectively,may change from a logic low to a logic high at a first time T1A′ and maychange from the logic high to the logic low at a second time T2A′. Atthis time, the first and third mode control signals TSAF11 and TSAF12may maintain the logic low. In the second mode, the pixel signal outputfrom the first AF pixel group PG_AF1 c may be the second pixel signalthat is a phase signal corresponding to the photo-charges generated bythe second pixel and the fourth pixel of the first AF pixel group PG_AF1c.

The fifth to eighth transmission control signals TS5A to TS8A providedthrough the fifth to eighth transmission control signal lines TGL21A,TGR21A, TGL22A, and TGR22A, respectively, may change from a logic low toa logic high at a third time T3A′ and may change from the logic high tothe logic low at a fourth time T4A′. At this time, the second modecontrol signal TSAF21 and the fourth mode control signal TSAF22 maymaintain the logic low. In the second mode, the pixel signal output fromthe second AF pixel group PG_AF2 c may be the first pixel signal that isa phase signal corresponding to the photo-charges generated by the firstpixel and the third pixel of the second AF pixel group PG_AF2 c.

In the second mode, the image sensor according to an exemplaryembodiment may perform the AF function in the direction X by using thefirst pixel signal output from the first AF pixel group PG_AF1 c and thesecond pixel signal output from the second AF pixel group PG_AF2 c.Accordingly, in the second mode, the image sensor may provide arelatively high speed AF function.

FIGS. 9A and 9B are diagrams illustrating another exemplary connectionbetween the row driver 140 and the pixel array 110 of FIG. 2 andillustrate a part of the pixel array 110 and the transmission controlsignal lines connected to a part of the pixel array 110. In describingFIGS. 9A and 9B, redundant descriptions of the same symbols orcomponents as in FIGS. 3 and 7 may be omitted. The pixel array 110 ofFIG. 2 may include at least one of a fifth pixel array 110_2 a and asixth pixel array 110_2 b.

Referring to FIG. 9A, the fifth pixel array 110_2 a may include aplurality of pixel groups PGd and a plurality of AF pixel groups PG_AFd.The plurality of pixels PX included in first to third pixel groups PG1 dto PG3 d may be connected to the transmission control signal line TG1A.The plurality of pixels PX included in fourth to sixth pixel groups PG4d to PG6 d may be connected to the transmission control signal lineTG2A.

Some of the pixels PX included in the plurality of AF pixel groupsPG_AFd may be connected to one corresponding line among the transmissioncontrol signal lines TG1A and TG2A and the other of the pixels includedin the plurality of AF pixel groups PG_AFd may be connected to onecorresponding line of the mode control signal lines TGELA and TGERA. Forexample, among the pixels PX included in the first AF pixel group PG_AF1d, the first pixel and the third pixel disposed in the first column maybe connected to the first mode control signal line TGELA, and the secondpixel and the fourth pixel disposed in the second column may beconnected to the transmission control signal line TG1A. Alternatively,for example, among the pixels PX included in the second AF pixel groupPG_AF2 d, the first pixel and the third pixel disposed in the firstcolumn may be connected to the transmission control signal line TG2A,and the second pixel and the fourth pixel disposed in the second column.may be connected to the second mode control signal line TGERA.

In the AF operation of the second mode, the first mode control signalprovided to the first mode control signal line TGELA may maintain thelogic low. In addition, the first mode control signal provided to thesecond mode control signal line TGERA may maintain the logic low.

In an exemplary embodiment, when the transmission control line TG1Aconnected to N numbers of pixels PX on a first row in the firstdirection X, and the first mode control signal line TGELA connected to Knumbers of pixels PX in the first row in the first direction X, the Kmay be less than or equal to 1/7 of the N. It is understood, however,that one or more other exemplary embodiments are not limited thereto.

Referring to FIG. 9B, the sixth pixel array 110_1 b may include aplurality of pixel groups PGe and a plurality of AF pixel groups PG_AFe.The plurality of pixels PX included in the plurality of pixel groups PGemay be connected to one corresponding line of the transmission controlsignal lines TG1A and TG2A. Some of the pixels PX included in theplurality of AF pixel groups PG_AFe may be connected to onecorresponding line among the transmission control signal lines TG1A andTG2A, and the other of the pixels PX included in the plurality of AFpixel groups PG_AFe may not be connected to the transmission controlsignal lines TG1A and TG2A.

Referring to FIGS. 9A and 9B, the image sensor according to an exemplaryembodiment may perform the AF operation of the second mode. The imagesensor may perform the AF function in the first direction X by using thesecond pixel signal output from the first AF pixel group PG_AF1 d orPG_AF1 e and the first pixel signal output from the second AF pixelgroup PG_AF2 d or PG_AF2 e, thereby providing a relatively high speed AFfunction.

FIG. 10A is an exemplary layout of a first pixel group PG1 e and a firstAF pixel group PG_AF1 e included in the sixth pixel array 110_2 b ofFIG. 9B. FIG. 10B is a cross-sectional view taken along line X1-X2 ofFIG. 10A. FIG. 10C is an exemplary circuit diagram of the first AF pixelgroup PG_AF1 e of FIG. 10A.

Referring to FIGS. 10A and 10B, a substrate 101 may include a firstpixel group region APG in which a first pixel group (for example, PG1 eof FIG. 9B) is formed and a first AF pixel group region APG in which afirst AF pixel group (for example, PG_AF1 e of FIG. 1B) is formed. Thesubstrate 101 may be a silicon wafer, a silicon on insulator (SOI)substrate, or a semiconductor epitaxial layer. The substrate 101 mayinclude a first surface 101 f and a second surface 101 b facing oropposing each other. For example, the first surface 101 f may be a frontsurface of the substrate 101, and the second surface 101 b may be a rearsurface of the substrate 101. Light may be incident on the secondsurface 101 b.

A pixel isolation layer 107 having a planar mesh structure may bedisposed on the substrate 101. The substrate 101 may includesemiconductor layers 101_1 to 101_4 and 101_1A to 101_4A separated bythe pixel isolation layer 107. In the present exemplary embodiment, eachof the semiconductor layers 101_1 to 101_4 and 101_1A to 101_4A may bedoped with impurities of a first conductivity type (for example,P-type).

Well regions 111_1, 111_2, 111_1A, and 111_2A doped with impurities of asecond conductivity type (for example, N-type) may be respectivelydisposed in the semiconductor layers 101_1 to 101_4 and 101_1A to101_4A. The well regions 111_1, 111_2, 111_1A, and 111_2A may bearranged in a matrix in the first and second directions X and Y in aplan view of the first and second directions X and Y.

Each of the well regions 111_1, 111_2, 111_1A, and 111_2A formed in thesemiconductor layers 101_1 to 101_4 and 101_1A to 101_4A may form aphotosensitive element, for example, a photodiode. Thus, the first tofourth pixels of the first pixel group PG1 e may be respectively formedin the first to fourth semiconductor layers 101_1 to 101_4 of the firstpixel group region AGP. In addition, the first to fourth pixels of thefirst AF pixel group PG_AF1 e may be respectively formed in the first tofourth semiconductor layers 101_1A to 101_4A of the first AF pixel groupregion APG_AF.

In the present exemplary embodiment, the second well region 111_2Aformed in the second semiconductor layer 101_2A of the first AF pixelgroup region APG_AF may be larger than the first well region 111_1Aformed in the first semiconductor layer 101_1A of the first AF pixelgroup region APG_AF. Further, in the present exemplary embodiment, thesecond well region 111_2A formed in the second semiconductor layer101_2A of the first AF pixel group region APG_AF may be larger than thefirst well region 111_1 and the second well region 111_2 respectivelyformed in the first semiconductor layer 101_1 and the secondsemiconductor layer 101_2 of the first pixel group region AGP. Since atransmission gate electrode is not formed in the first semiconductorlayer 101_1A of the first AF pixel group region APG_AF, the second wellregion 111_2A may be formed relatively large and a full well capacity(FWC) of the second well region 111_2A may increase.

Transmission gate electrodes 102_1 to 102_4, 102_2A, and 204_4A, whichare gate electrodes of the transmission transistor, may be formed on thefirst surface 101 f of the semiconductor layers 101_1 to 101_4 and101_1A to 101_4A. For example, the first to fourth transmission gateelectrodes 102_1 to 102_4 may be respectively formed on the first tofourth semiconductor layers 101_1 to 101_4 of the first pixel groupregion AGP. A second transmission gate electrode 102_2A and a fourthtransmission gate electrode 102_4A may be respectively formed on thesecond semiconductor layer 101_2A and the fourth semiconductor layer101_4A of the first AF pixel group region APG_AF. However, thetransmission gate electrode may not be formed on the first semiconductorlayer 101_1A and the third semiconductor layer 101_3A of the first AFpixel group region AGP_AF.

A first contact GCT to which a ground voltage is applied may be formedin the first AF pixel group region AGP_AF. The first contact GCT mayprovide the ground voltage provided from a metal line CL to the first tofourth semiconductor layers 101_1A to 101_4A of the first AF pixel groupregion APG_AF. In the present exemplary embodiment, the first contactGCT may be in contact with a P-type doped region of the substrate 101,and the ground voltage may also be applied to the first to fourthsemiconductor layers 101_1 to 101_4 through the P-type doped region.Accordingly, since the first contact GCT and the P-type doped region areformed, a dark current may be prevented from occurring in the first AFpixel group region APG_AF.

In contrast to this, the first contact GCT to which the ground voltageis applied and the P-type doped region in contact with the first contactGCT may not be formed in the first pixel group region AGP. Since thefirst contact GCT is not formed in the first pixel group region AGP, thefirst to fourth semiconductor layers 101_1 to 101_4 of the first pixelgroup region AGP may be formed to be large (or relatively large), andspaces in which the well regions (for example, 111_1 and 111_2) areformed may be secured in the first to fourth semiconductor layers 101_1to 101_4 of the one pixel group PG1 e.

A second contact 105 to which a predetermined voltage (for example, apower supply voltage VPIX of FIG. 10C) is applied may be formed in thefirst AF pixel group region AGP_AF. The second contact 105 may be formedunder the first well region 111_1A and may be in contact with the firstwell region 111_1A. As the power supply voltage is applied to the secondcontact 105, electrons of the first well region 111_1A may be preventedfrom diffusing to the outside of the first well region 111_1A. AlthoughFIG. 10B illustrates that the second contact 105 is formed under thefirst surface 101 f, the inventive concept(s) is not limited thereto.When the transmission transistor is formed in the first semiconductorlayer 101_1 and the third semiconductor layer 101_3, a doped region maybe formed in contact with an N-type doped region of the transmissiontransistor, and the power supply voltage may be applied to the dopedregion. Although FIG. 10A illustrates that the second contact 105 isformed over the first semiconductor layer 101_1A and the thirdsemiconductor layer 101_3A, the inventive concept(s) is not limitedthereto. In an exemplary embodiment, the second contact 105 may beformed in each of the first semiconductor layer 101_1A and the thirdsemiconductor layer 101_3A.

One floating diffusion region FD may be formed between the first tofourth semiconductor layers 101_1 to 101_4 of the first pixel groupregion APG, and a floating diffusion region FDA may be formed betweenthe first to fourth semiconductor layers 101_1A and 101_4A of the firstAF pixel group region APG_AF. In the present exemplary embodiment, thefloating diffusion regions FD and FDA may be doped with N-typeimpurities.

A reset gate electrode 103_1, a drive gate electrode 103_2, and aselection gate electrode 103_3, which are gate electrodes of the resettransistor, the drive transistor, and the selection transistor,respectively, may be formed in the first pixel group region AGP. A resetgate electrode 103_1A, a drive gate electrode 103_2A, and a selectiongate electrode 103_3A, which are gate electrodes of the resettransistor, the drive transistor, and the selection transistor,respectively, may be formed in the first AF pixel group region AGP_AF.

Referring to FIG. 10C, a first pixel of the first AF pixel group PG_AF1e may include a first photodiode PD11A, and a third pixel of the firstAF pixel group PG_AF1 e may include a third photodiode PD13A. The groundvoltage may be applied to anode terminals of the first photodiode PD11Aand the third photodiode PD13A, and the power supply voltage VPIX may beapplied to cathode terminal thereof. That is, each of the first pixeland the third pixel of the first AF pixel group PG_AF1 e may not includea transmission transistor. Each of the first pixel and the third pixelof the first AF pixel group PG_AF1 e may be electrically separated fromthe floating diffusion region FDA.

A second pixel of the first AF pixel group PG_AF1 e may include a secondphotodiode PD12A, a second transmission transistor TX12A, a selectiontransistor SX1A, a drive transistor SF1A, and a reset transistor RX1A. Afourth pixel of the first AF pixel group PG_AF1 e may include a fourthphotodiode PD14A, a fourth transmission transistor TX14A, a selectiontransistor SX1A, a drive transistor SF1A, and a reset transistor RX1A.The second pixel and the fourth pixel may form a shared pixel structurein which the floating diffusion region FDA is shared and the selectiontransistor SX1A, the drive transistor SF1A, and the reset transistorRX1A are shared with each other.

The second transmission transistor TX12A and the fourth transmissiontransistor TX14A may transmit photo-charges generated by the secondphotodiode PD2A and the fourth photodiode PD4A according to (or basedon) the transmission control signal TSA to the floating diffusion regionFDA. The transmission control signal TSA may be transmitted to thesecond transmission transistor TX12A and the fourth transmissiontransistor TX14A through the transmission control signal line TG1A ofFIG. 7C.

The reset transistor RX1A may transmit the power supply voltage VPIXconnected to a drain electrode of the reset transistor RX1A to thefloating diffusion region FDA in response to (or based on) a resetcontrol signal RS1A. The drive transistor SF1A may be controlledaccording to (or based on) the amount of photo-charges accumulated inthe floating diffusion region FDA. The selection transistor SX1A mayoutput a pixel signal VOUTA to the CDS (for example, 151 of FIG. 2)through the column output line in response to the selection signalSELS1.

FIG. 11A is another exemplary layout of the first pixel group PG1 e andthe first AF pixel group PG_AF1 e included in the sixth pixel array110_2 b of FIG. 9B. FIG. 11B is an exemplary circuit diagram of thefirst AF pixel group PG_AF1 e′ of FIG. 11A. In describing FIG. 11A andFIG. 11B, redundant descriptions of the same symbols or components as inFIGS. 10A and 10C may be omitted.

Referring to FIGS. 11A and 11B, a first transmission gate electrode102_1A may be formed on the first semiconductor layer 101_1A of a firstAF pixel group region APG_AF′, and a third transmission gate electrode102_3A may be formed on the third semiconductor layer 101_3A of thefirst AF pixel group region APG_AF′.

A first pixel and a third pixel of the first AF pixel group PG_AF1 e′may respectively include a first transmission transistor TX11A and athird transmission transistor TX13A. The first transmission transistorTX11A may be connected between the first photodiode PD11A and thefloating diffusion region PDA, and the third transmission transistorTX13A may be connected to the third photodiode PD13A and the floatingdiffusion region FDA.

The ground voltage may be applied to the first transmission gateelectrode 102_1A of the first transmission transistor TX11A and thethird transmission gate electrode 102_3A of the third transmissiontransistor TX13A. Accordingly, the first transmission transistor TX11Aand the third transmission transistor TX13A of the first AF pixel groupPG_AF1 e′ may block connection of the first photodiode PD11A and thethird photodiode PD13A to the floating diffusion region FDA.

FIGS. 12A to 12C are diagrams illustrating another exemplary connectionbetween the row driver 140 and the pixel array 110 of FIG. 2 andillustrate a part of the pixel array 110 and the transmission controlsignal lines connected to a part of the pixel array 110. In describingFIGS. 12A to 12C, redundant descriptions of the same symbols orcomponents as in FIG. 3 may be omitted. The pixel array 110 of FIG. 2may include at least one of seventh to ninth pixel arrays 110_3, 110_3a, and 110_3 b.

Referring to FIG. 12A, the seventh pixel array 110_3 may include aplurality of pixel groups PGf and a plurality of AF pixel groups PG_AFf.Each of the plurality of pixel groups PGf may include eight pixels PXarranged in two rows and four columns. Each of the plurality of pixelgroups PGf may include four microlenses ML arranged over the pluralityof pixels PX. Each of the plurality of pixel groups PG may include afirst pixel disposed in a first row and a first column, a second pixeldisposed in the first row and a second column, a third pixel disposed inthe first row and a third column, a fourth pixel disposed in the firstrow and a fourth column, a fifth pixel disposed in a second row and thefirst column, a sixth pixel disposed in the second row and the secondcolumn, a seventh pixel disposed in the second row and the third column,and an eighth pixel disposed in the second row and the fourth column. Inthe present exemplary embodiment, the first to eighth pixels included inthe same pixel group among the plurality of pixel groups PGf may sharethe floating diffusion region.

The first pixels included in the first to third pixel groups PG1 f toPG3 f may be connected to a first transmission control signal lineTGL11B, the second pixels included in the first to third pixel groupsPG1 f to PG3 f may be connected to a second transmission control signalline TGR11B, the third pixels included in the first to third pixelgroups PG1 f to PG3 f may be connected to a third transmission controlsignal line TGL12B, and the fourth pixels included in the first to thirdpixel groups PG1 f to PG3 f may be connected to a fourth transmissioncontrol signal line TGR12B. The fifth pixels included in the first tothird pixel groups PG1 f to PG3 f may be connected to a fifthtransmission control signal line TGL13B, the sixth pixels included inthe first to third pixel groups PG1 f to PG3 f may be connected to asixth transmission control signal line TGR13B, the seventh pixelsincluded in the first to third pixel groups PG1 f to PG3 f may beconnected to a seventh transmission control signal line TGL14B, and theeighth pixels included in the first to third pixel groups PG1 f to PG3 fmay be connected to an eighth transmission control signal line TGR14B.

The first pixels included in the fourth to sixth pixel groups PG4 f toPG6 f may be connected to a ninth transmission control signal lineTGL21B, the second pixels included in the fourth to sixth pixel groupsPG4 f to PG6 f may be connected to a tenth transmission control signalline TGR21B, the third pixels included in the fourth to sixth pixelgroups PG4 f to PG6 f may be connected to an eleventh transmissioncontrol signal line TGL22B, and the fourth pixels included in the fourthto sixth pixel groups PG4 f to PG6 f may be connected to a twelfthtransmission control signal line TGR22B. The fifth pixels included inthe fourth to sixth pixel groups PG4 f to PG6 f may be connected to athirteenth transmission control signal line TGL23B, the sixth pixelsincluded in the fourth to sixth pixel groups PG4 f to PG6 f may beconnected to a fourteenth transmission control signal line TGR23B, theseventh pixels included in the fourth to sixth pixel groups PG4 f to PG6f may be connected to a fifteenth transmission control signal lineTGL24B, and the eighth pixels included in the fourth to sixth pixelgroups PG4 f to PG6 f may be connected to a sixteenth transmissioncontrol signal line TGR24B.

Some of the pixels PX included in the plurality of AF pixel groupsPG_AFf may be connected to a corresponding transmission control signalline among the transmission control signal lines TGL11B to TGL14B,TGR11B to TGR14B, TGL21B to TGL24B, and TGR21B to TGR24B, and the otherof the pixels PX included in the plurality of AF pixel groups PG_AFf maybe connected to the corresponding transmission control signal line amongthe mode control signal lines TGEL1B, TGEL2B, TGER1B, and TGER2B. Forexample, the first pixel and the third pixel included in the first AFpixel group PG_AF1 f may be connected to the first mode control signalline TGEL1B, and the fifth pixel and the seventh pixel included in thefirst AF pixel group PG_AF1 f may be connected to the third mode controlsignal line. TGEL2B. The second, fourth, sixth, and eighth pixelsincluded in the first AF pixel group PG_AF1 f may be respectivelyconnected to the second, fourth, sixth, and eighth transmission controlsignal lines TGR11B, TGR12B, TGR13B, and TGR14B. In addition, forexample, the second pixel and the fourth pixel included in the second AFpixel group PG_AF2 f may be connected to the second mode control signalline TGER1B, and the sixth pixel and the eighth pixel included in thesecond AF pixel group PG_AF2 f may be connected to the fourth modecontrol signal line TGER2B. The first, third, fifth, and seventh pixelsincluded in the second AF pixel group PG_AF2 f may be respectivelyconnected to the first, third, fifth, and seventh transmission controlsignal lines TGL21B, TGL22B, TGL23B, and TGL24B.

In the AF operation of the first mode, the transmission control signalsprovided through the first, third, fifth, and seventh transmissioncontrol signal lines TGL11B, TGL12B, TGL13B, and TGL14B maysimultaneously change from a logic low to a logic high. Thereafter, thetransmission control signals provided through the second, fourth, sixth,and eighth transmission control signal lines TGR11B, TGR12B, TGR13B, andTGR14B may simultaneously change from the logic low to the logic high.At this time, the first mode control signal and the third mode controlsignal provided through the first mode control signal line TGEL1B andthe third mode control signal line TGEL2B may change from the logic lowto the logic high at the same timing as the timing of the firsttransmission control signal.

In the first mode, the transmission control signals provided through theninth, eleventh, thirteenth, and fifteenth transmission control signallines TGL21B, TGL22B, TGL23B, and TGL24B may simultaneously change fromthe logic low to the logic high. Thereafter, the transmission controlsignals provided through the tenth, twelfth, fourteenth, and sixteenthtransmission control signal lines TGR21B, TGR22B, TGR23B, and TGR24B maysimultaneously change from the logic low to the logic high. At thistime, the second mode control signal and the fourth mode control signalprovided through the second mode control signal line TGER1B and thefourth mode control signal line TGER2B may change from the logic low tothe logic high at the same timing as the timing of the tenthtransmission control signal provided to the tenth transmission controlsignal line TGR21B.

Conversely, in the AF operation of the second mode, while thetransmission control signals provided through the first to eighthtransmission control signal lines TGL11B to TGL14B and TGR11B to TGR14Bare changed, the first mode control signal and the third mode controlsignal provided through the first mode control signal line TGEL1B andthe third mode control signal line TGEL2B, respectively, may maintainthe logic low. In addition, while the transmission control signalsprovided through the ninth to sixteenth transmission control signallines TGL21B to TGL24B and TGR21B to TGR24B are changed, the second modecontrol signal and the fourth mode control signal provided through thesecond mode control signal line TGER1B and the third mode control signalline TGER2B, respectively, may maintain the logic low. The image sensormay perform the AF function in the first direction X by using the secondpixel signal output from the first AF pixel group PG_AF1 f and the firstpixel signal output from the second AF pixel group PG_AF2 f.

Accordingly, the image sensor may generate AF information by using eachof the plurality of pixel groups PGf and the plurality of AF pixelgroups PG_AFf by performing the AF operation of the first mode. Inaddition, the image sensor may generate the AF information by using theplurality of AF pixel groups PG_AFf by performing the AF operation ofthe second mode and may provide a relatively high speed AF function.

In an exemplary embodiment, when the first transmission control lineTGL11B connected to N numbers of pixels PX on a first row in the firstdirection X, the second transmission control line TGR11B connected to Mnumbers of pixels PX in the first row in the first direction X, and thefirst mode control signal line TGEL1B connected to K numbers of pixelsPX in the first row in the first direction X, the K may be less than orequal to ⅔ of each of the N and the M. It is understood, however, thatone or more other exemplary embodiments are not limited thereto.Referring to FIG. 12B, the eighth pixel array 110_3 a may include aplurality of pixel groups PGg and a plurality of AF pixel groups PG_AFg.The plurality of pixels PX included in first to third pixel groups PG1 gto PG3 g may be connected to the transmission control signal lines TG11Bto TG14B. The plurality of pixels PX included in fourth to sixth pixelgroups PG4 g to PG6 g may be connected to the transmission controlsignal lines TG21B to TG24B.

In the present exemplary embodiment, the pixels PX over which the samemicrolens ML is formed may be connected to the same transmission controlsignal line. For example, one microlens ML may be formed over the firstpixel and the second pixel of the first pixel group PG1 g, and the firstpixel and the second pixel may be connected to the same transmissioncontrol signal line TG11B.

Some of the pixels PX included in the plurality of AF pixel groupsPG_AFg may be connected to a corresponding line among the transmissioncontrol signal lines TG11B to TG14B and TG21B to TG24B, and the other ofthe pixels PX included in the plurality of AF pixel groups PG_AFg may beconnected to corresponding lines among the mode control signal linesTGEL1B, TGEL2B, TGER1B, and TGER2B. For example, first, third, fifth,and seventh pixels arranged in the first and third columns among thepixels PX included in the first AF pixel group PG_AF1 g may be connectedto the first mode control signal line TGEL1B and the third mode controlsignal line TGEL2B, and second, fourth, sixth, and eighth pixelsarranged in the second and fourth columns may be connected to thetransmission control signal lines TG11B to TG14B. Alternatively, forexample, the first, third, fifth, and seventh pixels arranged in thefirst and third columns among the pixels PX included in the second AFpixel group PG_AF2 g may be connected to the transmission control signallines TG21B to TG24B, and the second, fourth, sixth, and eighth pixelsarranged in the second and fourth columns may be connected to the secondmode control signal line TGER1B and the fourth mode control signal lineTGER2B.

In the AF operation of the second mode, the first mode control signaland the third mode control signal provided to the first mode controlsignal line TGEL1B and the third mode control signal line TGEL2B maymaintain a logic low. In addition, the second mode control signal andthe fourth mode control signal provided to the second mode controlsignal line TGER1B and the fourth mode control signal line TGER2B maymaintain the logic low.

In an exemplary embodiment, when the transmission control line TG11Bconnected to N numbers of pixels PX on a first row in the firstdirection X, and the first mode control signal line TGEL1B connected toK numbers of pixels PX in the first row in the first direction X, the Kmay be less than or equal to 2/7 of the N. It is understood, however,that one or more other exemplary embodiments are not limited thereto.

Referring to FIG. 12C, the ninth pixel array 110_3 b may include aplurality of pixel groups PGh and a plurality of AF pixel groups PG_AFh.The plurality of pixels PX included in the plurality of pixel groups PGhmay be connected to corresponding lines among the transmission controlsignal lines TG11B to TG14B and TG21B to TG24B. Some of the pixels PXincluded in the plurality of AF pixel groups PG_AFh may be connected toa corresponding line among the transmission control signal lines TG11Bto TG14B and TG21B to TG24B, and the other of the pixels PX included inthe plurality of AF pixel groups PG_AFh may not be connected to thetransmission control signal lines TG11B to TG14B and TG21B to TG24B. Forexample, the pixel PX not connected to the transmission control signallines TG11B to TG14B and TG21B to TG24B may not include the transmissiontransistor or may not apply the ground voltage to a gate electrode ofthe transmission transistor.

FIGS. 13A to 13C are diagrams illustrating another exemplary connectionbetween the row driver 140 and the pixel array 110 of FIG. 2 andillustrate a part of the pixel array 110 and the transmission controlsignal lines connected to a portion of the pixel array 110. Indescribing FIGS. 13A to 13C, redundant descriptions of the same symbolsor components as in FIG. 3 may be omitted. The pixel array 110 of FIG. 2may include at least one of tenth to twelfth pixel arrays 110_4, 110_4a, and 110_4 b.

Referring to FIG. 13A, the seventh pixel array 110_4 may include aplurality of pixel groups PGi and a plurality of AF pixel groups PG_AFi.Each of the plurality of pixel groups PGi may include sixteen pixels PXarranged in four rows and four columns. Each of the plurality of pixelgroups PGi may include four microlenses ML arranged over the pluralityof pixels PX. One microlens ML may be disposed over four pixels PXarranged adjacent to each other among the plurality of pixels PXincluded in one pixel group. The microlenses ML included in the seventhpixel array 110_4 may have the same shape and a constant size. In thepresent exemplary embodiment, the pixels PX included in the same pixelgroup among the plurality of pixel groups PG may share the floatingdiffusion region.

The pixels PX included in first to third pixel groups PG1 i to PG3 i maybe connected to corresponding lines among transmission control signallines TGL11C to TGL14C and TGR11C to TGR14C. The pixels PX included infourth to sixth pixel groups PG4 i to PG6 i may be connected tocorresponding lines among transmission control signal lines TGL21C toTGL24C and TGR21C to TGR24C.

Some of the pixels PX included in the plurality of AF pixel groupsPG_AFi may be connected to a corresponding line among the transmissioncontrol signal lines TGL11C to TGL14C, TGR11C to TGR14C, TGL21C toTGL24C, and TGR21C to TGR24C, and the other of the pixels PX included inthe plurality of AF pixel groups PG_AFi may be connected tocorresponding lines among the mode control signal lines TGEL1C to TGEL4Cand TGER1C to TGER4C. For example, the pixels PX arranged in the firstand third columns of the first AF pixel group PG_AF1 i may be connectedto the mode control signal lines TGEL1C to TGEL4C, and the pixels PXarranged in the second and fourth columns of the first AF pixel groupPG_AFli may be connected to the transmission control signal lines TGR11Cto TGR14C. In addition, for example, the pixels PX arranged in the firstand third columns of the second AF pixel group PG_AF2 i may be connectedto the transmission control signal lines TGL21C to TGL24C, and thepixels PX arranged in the second and fourth columns of the second AFpixel group PG_AF2 i may be connected to the mode control signal linesTGER1C to TGER4C.

In the AF operation of the first mode, the transmission control signalsprovided through the first, third, fifth, and seventh transmissioncontrol signal lines TGL11C, TGL12C, TGL13C, and TGL14C maysimultaneously change from a logic low to a logic high. Thereafter, thetransmission control signals provided through the second, fourth, sixth,and eighth transmission control signal lines TGR11C, TGR12C, TGR13C, andTGR14C may simultaneously change from the logic low to the logic high.At this time, the mode control signals provided through the mode controlsignal lines TGEL1C, TGEL2C, TGEL3C, and TGEL4C may change from thelogic low to the logic high at the same timing as the timing of thefirst transmission control signal provided to the first transmissioncontrol signal line TGL11C and may be activated at the same timing asthe timing of the first transmission control signal provided to thefirst transmission control signal line TGL11C.

In the first mode, the transmission control signals provided through theninth, eleventh, thirteenth, and fifteenth transmission control signallines TGL21C, TGL22C, TGL23C, and TGL24C may simultaneously change fromthe logic low to the logic high. Thereafter, the transmission controlsignals provided through the tenth, twelfth, fourteenth, and sixteenthtransmission control signal lines TGR21C, TGR22C, TGR23C, and TGR24C maysimultaneously change from the logic low to the logic high. At thistime, the mode control signals provided through the mode control signallines TGER1C, TGER2C, TGER3C, and TGER4C may change from the logic lowto the logic high at the same timing as the timing of the tenthtransmission control signal provided to the tenth transmission controlsignal line TGR21C.

Conversely, in the AF operation of the second mode, the transmissioncontrol signals provided through the first to eighth transmissioncontrol signal lines TGL11C to TGL14C and TGR11C to TGR14C maysimultaneously change from the logic low to the logic high. At thistime, the mode control signals provided through the mode control signallines TGEL1C to TGEL4C may maintain the logic low. In addition, thetransmission control signals provided through the ninth throughsixteenth transmission control signal lines TGL21C to TGL24C and TGR21Cto TGR24C may simultaneously change from the logic low to the logichigh. At this time, the mode control signals provided through the modecontrol signal lines TGER1C to TGER4C may maintain the logic low.

In the second mode, the image sensor may perform the AF function in thedirection X by using the second pixel signal output from the first AFpixel group PG_AF1 i and the first pixel signal output from the secondAF pixel group PG_AF2 i. Accordingly, the image sensor may provide arelatively high speed AF function by performing the AF operation of thesecond mode.

In an exemplary embodiment, when the first transmission control lineTGL11C connected to N numbers of pixels PX on a first row in the firstdirection X, the second transmission control line TGR11C connected to Mnumbers of pixels PX in the first row in the first direction X, and thefirst mode control signal line TGEL1C connected to K numbers of pixelsPX in the first row in the first direction X, the K may be less than orequal to ⅓ of each of the N and the M. It is understood, however, thatone or more other exemplary embodiments are not limited thereto.

Referring to FIG. 13B, the eleventh pixel array 110_4 a may include aplurality of pixel groups PGj and a plurality of AF pixel groups PG_AFj.The plurality of pixels PX included in first to third pixel groups PG1 jto PG3 j may be connected to transmission control signal lines TG11C andTG13C. The plurality of pixels PX included in fourth to sixth pixelgroups PG4 j to PG6 j may be connected to transmission control signallines TG21C and TG23C.

In the present exemplary embodiment, the pixels PX over which the samemicrolens ML is formed may be connected to the same transmission controlsignal line. For example, one microlens ML may be formed over the firstto fourth pixels arranged in the first and second rows and the first andsecond columns of the first pixel group PG1 j and may be connected tothe same transmission control signal line TG11C.

Some of the pixels PX included in the plurality of AF pixel groupsPG_AFj may be connected to a corresponding line among the transmissioncontrol signal lines TG11C, TG13C, TG21C, and TG23C, and the other ofthe pixels PX included in the plurality of AF pixel groups PG_AFj may beconnected to corresponding lines among the mode control signal linesTGEL1C, TGEL2C, TGER1C, and TGER2C. For example, the pixels arranged inthe first and third columns among the pixels PX included in the first AFpixel group PG_AF1 j may be connected to the mode control signal linesTGEL1C and TGEL3C, and the pixels arranged in the second and fourthcolumns may be connected to the transmission control signal lines TG11Cand TG13C. For example, the pixels arranged in the first and thirdcolumns among the pixels PX included in the second AF pixel group PG_AF2j may be connected to the transmission control signal lines TG21C andTG23C, and the pixels arranged in the second and fourth columns may beconnected to the mode control signal lines TGER1C and TGER3C and thefourth mode control signal line TGER2C.

In the AF operation of the second mode, the mode control signalsprovided through the mode control signal lines TGEL1C and TGEL3Cconnected to the first AF pixel group PG_AF1 j may maintain a logic low.In addition, the mode control signals provided through the mode controlsignal lines TGER1C and TGER3C connected to the second AF pixel groupPG_AF2 j may maintain the logic low.

In an exemplary embodiment, when the transmission control line TG11Cconnected to N numbers of pixels PX on a first row in the firstdirection X, and the first mode control signal line TGEL1C connected toK numbers of pixels PX in the first row in the first direction X, the Kmay be less than or equal to 1/7 of the N. It is understood, however,that one or more other exemplary embodiments are not limited thereto.

Referring to FIG. 13C, the twelfth pixel array 110_4 b may include aplurality of pixel groups PGk and a plurality of AF pixel groups PG_AFk.The plurality of pixels PX included in the plurality of pixel groups PGkmay be connected to a corresponding line among the transmission controlsignal lines TG11C, TG13C, TG21C, and TG23C. Some of the pixels PXincluded in the plurality of AF pixel groups PG_AFk may be connected toa corresponding line among the transmission control signal lines TG11C,TG13C, TG21C, and TG23C, and the other of the pixels PX included in theplurality of AF pixel groups PG_AFk may not be connected to thetransmission control signal lines TG11C, TG13C, TG21C, and TG23C. Forexample, the pixel PX not connected to the transmission control signallines TG11C, TG13C, TG21C, and TG23C may not include a transmissiontransistor, or the ground voltage may be applied to a gate electrode ofthe transfer transistor.

While the inventive concept(s) has been particularly shown and describedwith reference to exemplary embodiments above, it will be understoodthat various changes in form and details may be made therein withoutdeparting from the spirit and scope as embodied in at least thefollowing claims.

What is claimed is:
 1. An image sensor comprising: a pixel arrayincluding a plurality of image pixel groups and a plurality of autofocusing (AF) pixel groups, each of the plurality of image pixel groupsand the plurality of AF pixel groups including a plurality of pixels; afirst transmission control signal line connected to a first pixel ofeach of the plurality of image pixel groups; a second transmissioncontrol signal line connected to a second pixel of each of the pluralityof image pixel groups; a third transmission control signal lineconnected to a first pixel of each of the plurality of AF pixel groups;and a fourth transmission control signal line connected to a secondpixel of each of the plurality of AF pixel groups, wherein the fourthtransmission control signal line is electrically separated from thefirst to the third transmission control signal line, and wherein theeach of the plurality of image pixel group and the plurality of AF pixelgroups are disposed below a single microlens.
 2. The image sensor ofclaim 1, wherein, in a first mode, signals transmitted through the firstto the fourth transmission control signal line are activated, and in asecond mode, a signal transmitted through the fourth transmissioncontrol signal line is deactivated.
 3. The image sensor of claim 2,wherein the third transmission control signal line is a same line as atleast one of the first transmission control signal line and the secondtransmission control signal line, in the second mode, a signaltransmitted through the third transmission control signal line isactivated.
 4. The image sensor of claim 1, wherein the firsttransmission control signal line and the second transmission controlsignal line are electrically separated from each other.
 5. The imagesensor of claim 1, wherein the first transmission control signal lineand the second transmission control signal line are same line.
 6. Theimage sensor of claim 1, further comprising: a fifth transmissioncontrol signal line connected to a third pixel of each of the pluralityof image pixel groups; a sixth transmission control signal lineconnected to a fourth pixel of each of the plurality of image pixelgroups; a seventh transmission control signal line connected to a thirdpixel of each of the plurality of AF pixel groups; and an eighthtransmission control signal line connected to a fourth pixel of each ofthe plurality of AF pixel groups, wherein the eighth transmissioncontrol signal line is electrically separated from the fifth to theseventh transmission control signal line.
 7. The image sensor of claim6, wherein, in the first mode, signals transmitted through the fifth tothe eight transmission control signal line are activated, and in thesecond mode, a signal transmitted through the eight transmission controlsignal line is deactivated.
 8. The image sensor of claim 7, wherein theseventh transmission control signal line is a same line as at least oneof the fifth transmission control signal line and the sixth transmissioncontrol signal line, in the second mode, a signal transmitted throughthe seventh transmission control signal line is activated.
 9. The imagesensor of claim 6, wherein the fifth transmission control signal lineand the sixth transmission control signal line are electricallyseparated from each other.
 10. An image sensor comprising: a pixel arrayincluding a plurality of pixels on a first row in a first direction anda plurality pixels arranged on a second row in the first direction, thesecond row being arranged next to the first row in a second directionperpendicular to the first direction, the plurality of pixels on thefirst row including a first to an eighth pixels, the plurality of pixelson the second row including a first to an eighth pixels; and a firsttransmission control signal line connected to the first pixel, the fifthpixel, and the seventh pixel among the plurality of pixels on the firstrow, wherein the first pixel, the fifth pixel, and the seventh pixelamong the plurality of pixels on the first row are sequentially arrangedin the first direction, wherein each of the plurality of pixels on thefirst row is included in a corresponding pixel group among a pluralitypixel group, and each of the plurality of pixel group is disposed belowa single microlens.
 11. The image sensor of claim 10, further comprisinga second transmission control signal line connected to the second pixel,the sixth pixel, and the eighth pixel among the plurality of pixels onthe first row, and wherein the second pixel, the sixth pixel, and theeighth pixel among the plurality of pixels on the first row aresequentially arranged in the first direction.
 12. The image sensor ofclaim 11, further comprising a third transmission control signal lineconnected to the third pixel among the plurality pixels on the firstrow, and wherein the third pixel is disposed between the first pixel andthe fifth pixel among the plurality of pixels on the first row, and thethird transmission control signal line is different from the firsttransmission control signal line and the second transmission controlsignal line.
 13. The image sensor of claim 12, wherein the third pixelis configured to sense a green color.
 14. The image sensor of claim 12,further comprising a fourth transmission control signal line connectedto the second pixel, the fourth pixel, and the eighth pixel among theplurality pixels on the second row, and a fifth transmission controlsignal line connected to the sixth pixel among the plurality pixels onthe second row, and wherein the second pixel, the fourth pixel, thesixth pixel, and the eighth pixel are sequentially arranged in the firstdirection.
 15. The image sensor of claim 14, wherein the first to eighthpixels of the plurality of pixels on the first row are corresponding tothe first to eighth pixels of the plurality of pixels on the second row.16. The image sensor of claim 14, wherein, in a first mode, signalstransmitted through the first to the fifth transmission control signalline are activated, and in a second mode, signals transmitted throughthe third and fifth transmission control signal lines are deactivated.17. The image sensor of claim 16, wherein the fourth pixel among theplurality pixels on the first row and the fifth pixel among theplurality pixels on the second row are auto focusing pixels.
 18. Animage sensor comprising: a pixel array including a plurality of firstpixels on a first row in a first direction and a plurality of secondpixels arranged on a second row in the first direction, the second rowbeing arranged next to the first row in a second direction perpendicularto the first direction; a first transmission control line connected to Nnumbers of pixels of the plurality of first pixels; a secondtransmission control line connected to M numbers of pixels of theplurality of first pixels; a third transmission control line connectedto K numbers of pixels of the plurality first pixels, wherein each ofthe plurality of pixels on the first row is included in a correspondingpixel group among a plurality pixel group, and each of the plurality ofpixel group is disposed below a single microlens, wherein the N, the Mand the K are integer, and the K is less than or equal to ⅓ of each ofthe N and the M.
 19. The image sensor of claim 18, the thirdtransmission control line is connected to a plurality auto focusingpixel group among the plurality pixel group.
 20. The image sensor ofclaim 19, wherein the plurality of auto focusing pixel groups areconfigured to sense a green color.